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Main Authors: Krapp, Lothar Sebastian, Wirth, Laura
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.10243
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author Krapp, Lothar Sebastian
Wirth, Laura
author_facet Krapp, Lothar Sebastian
Wirth, Laura
contents The Fundamental Theorem of Statistical Learning states that a hypothesis space is PAC learnable if and only if its VC dimension is finite. For the agnostic model of PAC learning, the literature so far presents proofs of this theorem that often tacitly impose several measurability assumptions on the involved sets and functions. We scrutinize these proofs from a measure-theoretic perspective in order to explicitly extract the assumptions needed for a rigorous argument. This leads to a sound statement as well as a detailed and self-contained proof of the Fundamental Theorem of Statistical Learning in the agnostic setting, showcasing the minimal measurability requirements needed. As the Fundamental Theorem of Statistical Learning underpins a wide range of further theoretical developments, our results are of foundational importance: A careful analysis of measurability aspects is essential, especially when the theorem is used in settings where measure-theoretic subtleties play a role. We particularly discuss applications in Model Theory, considering NIP and o-minimal structures. Our main theorem presents sufficient conditions for the PAC learnability of hypothesis spaces defined over o-minimal expansions of the reals. This class of hypothesis spaces covers all artificial neural networks for binary classification that use commonly employed activation functions like ReLU and the sigmoid function.
format Preprint
id arxiv_https___arxiv_org_abs_2410_10243
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publishDate 2024
record_format arxiv
spellingShingle Measurability in the Fundamental Theorem of Statistical Learning
Krapp, Lothar Sebastian
Wirth, Laura
Machine Learning
Logic in Computer Science
Logic
Probability
Primary 68T05, 03C64, Secondary 28A05, 28A20, 03C98, 68T27, 12J15
The Fundamental Theorem of Statistical Learning states that a hypothesis space is PAC learnable if and only if its VC dimension is finite. For the agnostic model of PAC learning, the literature so far presents proofs of this theorem that often tacitly impose several measurability assumptions on the involved sets and functions. We scrutinize these proofs from a measure-theoretic perspective in order to explicitly extract the assumptions needed for a rigorous argument. This leads to a sound statement as well as a detailed and self-contained proof of the Fundamental Theorem of Statistical Learning in the agnostic setting, showcasing the minimal measurability requirements needed. As the Fundamental Theorem of Statistical Learning underpins a wide range of further theoretical developments, our results are of foundational importance: A careful analysis of measurability aspects is essential, especially when the theorem is used in settings where measure-theoretic subtleties play a role. We particularly discuss applications in Model Theory, considering NIP and o-minimal structures. Our main theorem presents sufficient conditions for the PAC learnability of hypothesis spaces defined over o-minimal expansions of the reals. This class of hypothesis spaces covers all artificial neural networks for binary classification that use commonly employed activation functions like ReLU and the sigmoid function.
title Measurability in the Fundamental Theorem of Statistical Learning
topic Machine Learning
Logic in Computer Science
Logic
Probability
Primary 68T05, 03C64, Secondary 28A05, 28A20, 03C98, 68T27, 12J15
url https://arxiv.org/abs/2410.10243